FR3101749A1 - High Contact Density Electrical Connection Kit - Google Patents

Abstract

Electrical connection assembly comprising two mating connectors (100, 200), each comprising electrically insulating plates (110, 210) parallel to each other, each having a face carrying signal carrying contacts (111, 211) and a face opposite one carrying at least one shield blade (112, 212) such that when the connectors are mated together, the plates (110, 210) are interposed between each other and the contacts (111, 211) are applied against each other and the shield blades (112, 212) are pressed against each other. FIGURE OF ABREGE: Fig. 3

Description

High contact density electrical connection assembly

BACKGROUND OF THE INVENTION

The present invention relates to the field of electrical connection more particularly in the aeronautical field.

Connection devices are known comprising a casing having a peripheral frame having an edge delimiting a first opening closed by a printed circuit board (commonly called a PCB) and an opposite edge on which is attached a plate provided with a second opening in next to at least one electrical connection interface of the printed circuit board. A well is fixed on said plate to extend from an edge of the second opening to the printed circuit board to receive one or more first connectors connected to the connection interface. The connection interface generally consists of metallized holes made in the printed circuit board and connected to conductive tracks of said board. The first connector comprises a rigid body having one end provided with "PRESS-FIT" type pins intended to be engaged in the metallized holes and an opposite end arranged to cooperate with a second homologous connector. The first connector is connected to the second connector by pins received by force in metallized holes.

Such connection devices are for example used in aircraft to connect the aircraft's computers to the avionics harness in accordance with the ARINC 600 standard. These computers are grouped together in a chassis (or "rackable" bay or box) having an opening for the installation of the computers and, on the contrary, a bottom which carries the connection device in such a way that the connection of the computer to the connection device is carried out automatically when the computer is placed in the bay, the contacts of the computer being embedded in the connection device once the computer is in position in the chassis. These connection devices are commonly referred to as bottom blocks or "rack-mount" case back blocks.

The programs executed on the computers generate increasingly high digital throughputs. Indeed, the number of parameters measured on aircraft has increased, as have the sampling rates. Signal transfer requirements have therefore greatly increased in aircraft and require relatively bulky and expensive connectors.

OBJECT OF THE INVENTION

The object of the invention is in particular to provide connection means having a simple structure and a relatively high signal transfer capacity.

To this end, provision is made according to the invention for an electrical connection assembly comprising a first connector and a second homologous connector, characterized in that the first connector comprises first electrically insulating plates, parallel to each other, each having a face carrying first signal transport contacts and an opposite face carrying at least a first shielding blade, the second connector comprises second electrically insulating plates, parallel to each other, each having a face carrying second signal transport contacts and an opposite face carrying at least a second shielding blade such that, when the first connector is connected to the second connector, the plates are intercalated one between the other and the first contacts are applied against the second contacts, and the first blade shield is applied against the second shield blade.

The connector of the invention allows a higher density of contacts than the known connector and also a signal transfer capacity which is also higher. In addition, between the opposite flat contacts an electrical coupling and a capacitive coupling are created, without noticeable break in the iterative impedance of the differential transmission line.

Other characteristics and advantages of the invention will become apparent on reading the following description of a particular and non-limiting embodiment of the invention.

Reference will be made to the accompanying drawings, among which:

Figure 1 is a perspective view of a connection device according to the invention;

Figure 2 is a schematic view of the connection device in cross section along the plane II of Figure 1;

Figure 3 is a partial schematic view, in cross section along a plane perpendicular to the plates, of two connectors connected to each other;

Figure 4 is a front view of the first connector;

Figure 5 is a schematic view, in section along line VV of Figure 4, of the first connector;

Figure 6 is a partial schematic view, in section along line VI-VI of Figure 3, of two connectors connected to each other.

With reference to the figures, the connection device according to the invention comprises a housing generally designated at 1 and a printed circuit board 10.

The box 1, of parallelepipedal shape, is delimited by a side wall 2, of closed contour, of which a free edge forms a first face 3.1 of the box 1 and an opposite edge is integral with a bottom wall forming a second face 3.2 of the housing 1. The side wall 2 forms a frame and extends perpendicular to the printed circuit board 10. The first face 3.1 is provided with a first opening 4.1 (delimited by the free edge of the side wall 2) and the second face 3.2 is provided with second openings 4.2.

The housing 1 comprises wells 5 each extending from an edge of one of the second openings 4.2 and having a free edge extending slightly set back from the plane of the first face 3.1.

The second face 3.2 is provided in a manner known per se with a keying device 6 in order to prevent assembly and connection errors.

Housing 1 has a monolithic structure: side wall 2, faces 3.1, 3.2 and wells 5 are one unitary piece. The case is the result of machining a block of material, here a metal such as aluminium. Other manufacturing methods are possible. Thus, as a variant, the housing can result from additive manufacturing or molding. For the tightest manufacturing tolerances, it is possible to carry out re-machining, in particular for the first face 3.1 which constitutes a reference for positioning the case 1 with respect to the printed circuit board 10.

The free edge of the side partition 2 is applied to a face 11 of the printed circuit board 10 which closes off the first opening 3.1 and which has an opposite face 12. Said face 11 is provided with a connection interface 13 which is connected to conductive tracks of the printed circuit board 10 and to a connection interface carried by the opposite face 12 and not shown here.

The connection interface 13 extends opposite the second opening 4.2 and is surrounded by the free edge of the well 5. The connection interface 13 here comprises metallized holes 14.

Two of the wells 5 each receive a first connector 100 comprising a dielectric support having a first end provided with conductors 101, 102 in the form of a pin which project from the dielectric support and are received by force in the metallized holes 14. The wells 5 are arranged to guide and position the first connector 100 with respect to the first connection interface 13. The conductors 101 of the first connector 100 have a flattened S-shaped cross section. The dielectric support of the first connector 100 comprises, opposite the conductors 101, first electrically insulating plates 110, parallel to each other, each having a face carrying first signal transport contacts 111 connected to the conductors 101 and a face opposite carrying a first shield blade 112 connected to the conductors 102.

Each first connector 100 is part of an electrical connection assembly also comprising a second homologous connector 200. The second connector comprises a dielectric support comprising, like the first connector 100, second electrically insulating plates 210, parallel to each other, each having a face carrying second signal transport contacts 211 and an opposite face carrying a second blade of shielding 212.

The contacts 111, 211 are arranged in conductive tracks extending parallel to a direction of mutual engagement of the connectors 100, 200 between them. The contacts 111, 211 have the form of stamped lamellae which are elastically deformable between a rest position in which the lamella projects from the conductive track and a deformed position in which the lamella is in the extension of the conductive track.

The shielding blades 112, 212 also comprise contacts formed by strips cut in the shielding strips 112, 212 and are elastically deformable between a rest position in which the strip projects from the shielding strip 112, 212 and a deformed position in which the strip is in the extension of the shielding strip 112, 212.

The contacts 111 and the shield blades 112 have reverse positions with respect to the contacts 211 and the shield blades 212 in such a way that, when the first connector 100 is connected to the second connector 200, the plates 110 are interposed between the plates 210 and conversely, the first contacts 111 are applied against the second contacts 211, and the first shield blades 112 are applied against the second shield blades 212. The contacts 111, 211 are narrow flat contacts for carrying signals and the blades shielding 112, 212 are wide flat contacts for the realization of interzone ground planes of contacts. The contacts 111, 211 and the shielding strips 112, 212 are all made here by stamping the same type of sheet metal, which allows standardization of the contacts for all types of signals. The width of the contacts 111, 211 is here determined so as to double the density of contacts compared to a conventional ARINC 600 connector equipped with standard 22 gauge contacts.

The plates 210 of the second connector 200 comprise ribs 220 each extending between two contacts 211 parallel to the conductive tracks and the plates 110 of the first connector 100 comprise grooves 120 each extending between two contacts 111 parallel to the conductive tracks to each receive a free edge of each rib 220.

A layer 300 of electrically insulating material extends between the first surface of the first connector 100 and the connection interface as far as the free edge of the side wall 2, the conductors 101 of the first connector 100 passing through the layer 300. The layer 300 has a thickness of about 0.6 mm. The electrically insulating material is an RTV silicone.

When second connector 200 is mated to first connector 100, plates 210 then extend like plates 110 into well 5 which protects them and the connection; the contacts of each pair of facing contacts 111 and 211 are applied against each other; the shielding blades of each pair of facing shielding blades 112, 212 are applied against each other; the free edge of each rib 120 is received in the groove 220 opposite.

The tolerance intervals of the box 1 obtained due to its monolithic construction are relatively tight (a few tenths of a millimeter) and thus make it possible to gain in positioning accuracy of the conductors of the first connectors 100 in the printed circuit board. This arrangement makes it possible to eliminate the body of the first connector 100 since the wall of the well 5 is positioned and dimensioned in a sufficiently precise manner for the casing 1 to be able to provide the mechanical resistance functions normally provided by the connector body. There is thus a pooling of the mechanical functions of the housing and of the connector.

The contacts of the first connector 100 and of the second connector 200 which face each other achieve an electrical coupling and a capacitive coupling, without noticeable break in the iterative impedance of the differential transmission line and allow a large bandwidth for the digital buses (up to a few Gbits/s).

The arrangement of contacts of the first connector 100 and of the second connector 200 thus makes it possible to replace in particular the "QUADRAX" type connectors by providing a greater density of contacts and therefore a better signal transfer capacity.

The shielding blades 112, 212 prevent capacitive coupling between the equipotentials from one plate 110, 210 to another.

The ribs 120 and the grooves 220 cooperate in the manner of mutually overlapping combs (thus forming chicane passages) and the electrically insulating material of the plates 110, 210 is chosen in such a way that the dielectric distances between adjacent contacts are artificially increased and the dielectric strength of the plates 110, 210 is much higher than that of air (particularly at low pressure). The combs are dimensioned and the material is chosen to allow, for example, a maximum potential difference of 2100 Vdc between two adjacent contacts at altitude 0. For a rib 120 of 0.5 mm engaged by 0.2 mm in the groove 220, the resulting clearance in air becomes 0.2 + 0.5 + 0.2 = 0.9mm. Taking into account that the dielectric strength conventionally used for dry ambient air is 3600V/mm, the comb structure will allow a potential difference of 0.9 x 3600V = 3240V. For air saturated with humidity, which is not the case with ventilated aircraft bays, the dielectric strength conventionally used is 1000V/mm and the comb structure will allow a potential difference of 0.9 x 1000 = 900V .

As the dielectric distance in the air between the conductors 110 is very low, even too low to withstand the aeronautical dielectric stresses, it is planned to add the layer 300 which is electrically insulating. Layer 300 is crushed between first connector 100 and the printed circuit board. The layer 300 is made of a material which is elastically deformable and which has electrical insulation performance superior to that of air.

Layer 300 is formed from a very liquid RTV resin and is formed as follows:

• at ambient pressure and temperature, the resin is introduced on top of the printed circuit board 10 through an opening in the side wall separated from the printed circuit board by a height greater than the desired thickness of the layer 300 The quantity of resin is defined so that the bottom of the dielectric support of the first connector 100 is immersed in the resin in order to guarantee the continuity of the electrical insulation. The resin height will be approximately 0.6mm as the gap between the bottom of the dielectric backing and the top of the circuit board is approximately 0.5mm;
• the device is placed in a depressurization chamber (objective 10 mBar) in order to guarantee the penetration of the resin into all the interstices or holes of the printed circuit board and to eliminate all the bubbles which could be present in the resin. This ensures homogeneity of the resin around the conductors 101 to be isolated from the ambient air.

Note that the housing 1 and the printed circuit board form a host mold for the liquid resin. The RTV resin used is for example a silicone resin and in particular that marketed under the reference "Snapsil TN3305" by the company Momentive. This silicone-based resin has a viscosity of 47 and can be used between -55°C and +125°C.

Preferably, for the production of the first connector 100, the contacts 111 and the shield blades 112 are stamped (cut and formed) in a single cutting and forming operation, making it possible to also form the conductors 101 ("Press-fit" pins ) and the reliefs for anchoring this assembly in the dielectric support of the connector 100. Said dielectric support is made of two sub-parts in which the metal strips and blades are mounted. At the junction point of the two sub-parts, the anchoring reliefs of the slats come into abutment. Then the two insulating sub-parts are preferably welded together by an ultrasonic welding technique, which allows local heating and thermoplastic welding while avoiding the use of glue or general heating which could be a factor. limiting for the mechanical precision of the connector. The anchoring reliefs are sized to form a mechanical connection resistant to any longitudinal displacement of the conductors 101, particularly during pressing operations (Press-fit assembly).

Of course, the invention is not limited to the embodiment described but encompasses any variant falling within the scope of the invention as defined by the claims.

In particular, the device may thus have a structure different from that described.

As a variant, it is possible to make wells to form cells each intended to accommodate a QUADRAX-type connector socket, which will make it possible to further improve the positioning precision of the QUADRAX-type connector sockets and to reduce the number of mechanical parts to be produced.

Although the means making it possible to increase the electrical path from one contact to the other are here a comb structure, other means are possible.

It is possible to use high-speed contacts to carry high currents: their paralleling, allowing the highest intensities, will be carried out at the level of the printed circuit board.

It is possible to use the first connectors of modular size by creating groups of small-signal contacts associated with each other by their dielectric support and associated with the shielding blade (or ground plane) mounted opposite the small-signal contacts. Each contact module (which would then look like a plate 110, 210 bearing the contacts 111, 211 and the shielding blade 112, 212) can be combined with another, and so on, to create a first connector having the desired size. The width of the first connectors would be constant (the width of the plate 110, 210) and only the height would vary.

The dielectric support can be made by injection of a thermoplastic or thermosetting resin.

The invention is applicable to all ARINC 600 computers and can be extended to any other type of computer connectors having the same needs, for example on EN4165 connectors.

Using the case as a lost mold is optional. Another solution is to locally inject this same RTV resin by maintaining it in the connector area by local waterproof barriers (made with a second more pasty RTV resin).

The housing may have a structure different from that described and be assembled.

The use of a layer of electrically insulating material is optional and will depend on the constraints of use of the device.

Claims (10)

Electrical connection assembly comprising a first connector (100) and a second homologous connector (200), characterized in that the first connector (100) comprises first electrically insulating plates (110), parallel to each other, each having a bearing first signal-carrying contacts (111) and an opposite face bearing at least a first shielding strip (112), the second connector (200) comprises second electrically insulating plates (210), parallel to each other, having each one face carrying second signal transport contacts (211) and an opposite face carrying at least one second shielding blade (212) such that, when the first connector (100) is connected to the second connector (200), the plates (110, 210) are interposed between each other and the first contacts (111) are applied against the second contacts (211), and the first shield blade (112) is applied against the second shield blade (212 ). Assembly according to claim 1, in which the contacts (111, 211) are arranged in conductive tracks extending parallel to a direction of mutual engagement of the connectors (100, 200) between them. Assembly according to Claim 2, in which the plates (210) of one of the connectors (200) comprise ribs (220) each extending between two conductive tracks parallel thereto and the plates (110) of the another connector (100) comprise grooves (120) each extending between two conductive tracks parallel thereto to each receive a free edge of each rib (220). Assembly according to any one of the preceding claims, the contacts (111, 211) have the form of stamped strips. Connection device, comprising a housing (1) having a first face (3.1) provided with a first opening (4.1) closed by a printed circuit board (10) and a second face (3.2) provided with a second opening ( 4.2) facing at least one connection interface (13) of the printed circuit board (10), at least one well (5) extending from an edge of the second opening (4.2) to the board printed circuit board (10) for receiving the first connector (100) of an electrical connection assembly according to any one of the preceding claims. Device according to Claim 5, in which the casing (1) comprises a wall (2) having a free edge of closed contour which bears against the printed circuit board (10) and which extends around the interface of connection (13), and a layer of electrically insulating material (300) extends between the first surface of the first connector (100) and the connection interface (13) as far as the free edge of said wall (2), the conductors (101) of the first connector (100) passing through the layer of electrically insulating material (300). Device according to Claim 6, in which the electrically insulating material is an RTV silicone. Device according to Claim 6 or 7, in which the layer of electrically insulating material (300) has a thickness of approximately 0.6 mm. Device according to any one of Claims 6 to 8, in which the connection interface (13) comprises plated holes (14) to receive the conductors (101) of the first connector (100). Device according to the preceding claim, in which the conductors (101) of the first connector (100) have an S-shaped cross-section.